FR3137006A1 - METHOD FOR MANUFACTURING A PLURALITY OF TURBOMACHINE BLADES - Google Patents

Abstract

Method (100) for manufacturing a plurality of blades (10) of height (Ha) comprising: providing a mold (30) comprising an internal cavity delimited by an internal side face (34) of the mold which is axisymmetric around a longitudinal axis (X), the lateral face (34) extending along the longitudinal axis (X) according to a height (Hf) which is greater than or equal to the height (Ha), the lateral face (34) defining a plurality of sections (34i) perpendicular to the longitudinal axis (X) of radius (Rfs), for each section (34i), the ratio between the height (Hf) of the lateral face (34) and the radius (Rfs) of the section (34i) being less than or equal to 2.0; cause the mold to rotate around the longitudinal axis with a rotation speed of between 200 rpm-1 and 800 rpm-1; pour a material into the internal cavity to form by centrifugation a tubular part (20) along the longitudinal axis (X). Abstract Figure: Figure 1

Description

METHOD FOR MANUFACTURING A PLURALITY OF TURBOMACHINE BLADES

The present description relates to a method of manufacturing a plurality of turbomachine blades.

To manufacture turbomachine blades, it is known to first produce a tubular part 20 (also called a “barrel”) and to machine blanks for turbomachine blades 10 or directly the turbomachine blades 10 from it. As visible in Figure 1a, the tubular part 20 extends along a first axis A1 between a first end and a second end and has a thickness in the radial direction. The blades 10 can thus be machined in the thickness of the tubular part 20 by being arranged circumferentially one after the other around the first axis A1. Thus, as visible in Figure 1b, each blade 10 extends substantially parallel to the first axis A1.

Ideally, as shown in , the radially internal face 24 of the tubular part 20 has, in a cutting plane comprising the first axis A1, a straight profile 25 which is aligned with the first axis A1. However, the tubular part 20 is generally obtained by vertical centrifugal casting which gives a parabolic profile to the internal face 24 of the tubular part 20. Thus, the tubular part 20 has a thickness e ₁ which is greater at the level of the first end than the thickness e ₂ at the level of the second end. The tubular part 20 therefore comprises a non-functional part 22, or surplus material, at the first end which does not participate in the production of the blades. The non-functional part 22 is therefore eliminated during the manufacturing of the blades 10, which reduces the efficiency of the manufacturing process.

Summary

A method of manufacturing a plurality of turbomachine blades of height is proposed, the method comprising:
- provide a mold comprising an internal cavity, the internal cavity being delimited by an internal lateral face of the mold which is axisymmetric around a longitudinal axis, the lateral face extending along the longitudinal axis at a height which is greater than or equal to at the height of each blade, the side face defining a plurality of sections perpendicular to the longitudinal axis, each section of the side face having a radius, the side face of the mold being such that, for each section, the ratio between the height of the side face and the radius of the section is less than or equal to 2.0;
- position the mold so that the longitudinal axis is aligned with the gravity field,
- cause the mold to rotate around the longitudinal axis with a rotation speed of between 200 rpm ^-1 and 800 rpm ^-1 ,
- pour a material into the internal cavity of the mold so as to form by centrifugation a tubular part extending along the longitudinal axis.

The tubular part obtained extends longitudinally between a lower end and an upper end at a height which coincides with the height of the side face of the mold. Furthermore, the tubular part has an external face which coincides with the side face of the mold. The external face of the tubular part is axisymmetric around the longitudinal axis. The tubular part defines a plurality of sections perpendicular to the longitudinal axis. Each section of the tubular part is associated with a corresponding section of the side face of the mold which is located at the same longitudinal position. Each section of the tubular part has an external radius which coincides with the radius of the corresponding section of the side face of the mold.

In addition, the tubular part thus obtained has an internal face which is substantially frustoconical around the longitudinal axis. In other words, the profile of the internal face of the tubular part in a section plane comprising the longitudinal axis is substantially a straight line segment forming an angle with the longitudinal axis. Such a profile of the internal face of the tubular part makes it possible to reduce, or even eliminate, the quantity of material forming a non-functional part of the tubular part. The process therefore makes it possible to reduce the initial quantity of material necessary to obtain the plurality of blades. In other words, the process improves the timing of the manufacturing of the plurality of turbomachine blades.

The term “functional” used in reference to the parts of the tubular part indicates whether the part thus qualified makes it possible to produce one or more blades. Thus, a functional part of the tubular part is a part which contains the blades with an excess thickness of material which is limited (such an excess thickness is of the order of a millimeter, preferably less than 10 mm, even preferably less than 5 mm ). The functional part of the tubular part may have a profile in a section plane comprising the longitudinal axis which has the shape of a parallelogram, one of the sides of which coincides with the external face of the tubular part. In a particular mode, the functional part of the tubular part has a profile in a section plane comprising the longitudinal axis which is rectangular. On the contrary, the non-functional part is a part which does not participate in the production of the blades. Therefore, the quantity of material forming the non-functional part is lost during the manufacturing of the blades. The non-functional part can be located radially inside the functional part.

The side face of the mold can be such that, for each section, the ratio between the height of the side face and the radius of the section is between 0.5 and 1.5, preferably between 0.75 and 1, 25, more preferably equal to 1.0.

The height of the side face of the mold can be between 150 mm and 2000 mm.

Each section of the side face of the mold extends in a plane perpendicular to the longitudinal axis. Each section has a circular shape centered on the longitudinal axis.

The radius of each section of the side face of the mold can be defined as being the distance separating the side face from the longitudinal axis in the plane perpendicular to the corresponding longitudinal axis of the section. The side face may include at least two sections whose radius is different from each other. The radius of each section of the side face can be determined as a function of the longitudinal position of the section on the side face, for example according to a linear law. Alternatively, the radius of each section of the side face may be identical.

The radius of each section of the side face of the mold can be between 150 mm and 1500 mm.

Each section of the tubular part extends in a plane perpendicular to the longitudinal axis.

The external face of the tubular part may have, in each section of the tubular part, a circular shape centered on the longitudinal axis.

The external radius of each section of the tubular part can be defined as being the distance separating the external face of the tubular part from the longitudinal axis in the plane perpendicular to the corresponding longitudinal axis of the section. The tubular part may comprise at least two sections whose external radius is different from each other. The external radius of each section of the tubular part can be determined as a function of the longitudinal position of the section on the tubular part, for example according to a linear law. Alternatively, the external radius of each section of the tubular part can be identical.

The internal face of the tubular part may have, in each section of the tubular part, a circular shape centered on the longitudinal axis.

Each section of the tubular part can have an internal radius. The internal radius of each section of the tubular part can be defined as being the distance separating the internal face of the tubular part from the longitudinal axis in the plane perpendicular to the corresponding longitudinal axis of the section. The internal radius of each section of the tubular part can be determined as a function of the longitudinal position of the section on the tubular part, for example according to a linear law.

The internal face of the tubular part [may have a frustoconical shape with a half-angle at the top defined by γ=g/(ω ² (Re ₀ -e _t ))] where
g is the acceleration of gravity;
ω is the rotation speed of the mold around the longitudinal axis;
Re ₀ is the external radius of the section of the tubular part located at the lower end of the tubular part;
e _t is a theoretical thickness which verifies (e _t /(Re ₀ -e _t ))≤0.7.

The mold may comprise at least one tubular wall extending along the longitudinal axis. The tubular wall may include the side face. The tubular wall of the mold can extend along the longitudinal axis between a lower end and an upper end.

The tubular part obtained may have a plurality of sections perpendicular to the longitudinal axis, the method further comprising determining a quantity of material to be poured into the mold so that each section of the tubular part has a thickness which is greater than or equal to a theoretical thickness e _t which verifies (e _t /(Re ₀ -e _t ))≤0.7 where Re ₀ is the external radius of the section of the tubular part which is located at a lower end of the tubular part. This ensures that the tubular part has sufficient thickness to manufacture a turbomachine blade whatever the longitudinal position considered on the tubular part. Among other words, the minimum theoretical thickness to manufacture a turbomachine blade whatever the longitudinal position considered on the tubular part.

The thickness of each section of the tubular part can be considered in a radial direction relative to the longitudinal axis. The thickness of each section of the tubular part can be defined as the difference between the external radius and the internal radius of the section.

The tubular part may comprise at least two sections whose thickness is different from one another. Alternatively, the thickness of each section of the tubular part can be identical.

In particular, the thickness of the section of the tubular part which is located at the upper end of the tubular part may be greater than or equal to a theoretical thickness which verifies (e _t /(Re ₀ -e _t ))≤ 0.7 where Re ₀ is the external radius of the section of the tubular part which is located at a lower end of the tubular part.

The functional part of the tubular part may have, for each section of the tubular part, a thickness considered in a radial direction relative to the longitudinal axis. The thickness of the functional part can be greater than or equal to the theoretical thickness for each section of the tubular part.

The internal cavity of the mold can be delimited by an internal lower face of the mold and an internal upper face of the mold, the lower face and the upper face being respectively connected to a lower end and an upper end of the side face, the lower face and the upper face preferably each being perpendicular to the longitudinal axis.

The lower face and/or the upper face of the mold can each be axisymmetrical around the longitudinal axis.

The mold may include a lower wall and an upper wall each extending transversely to the longitudinal axis. The upper wall and the lower wall can be respectively connected to a lower end and an upper end of the tubular wall of the mold. The lower wall and the upper wall may respectively comprise the internal lower face and the internal upper face. The top wall may include an opening for pouring material into the internal cavity. The lower wall may have no opening.

The side face of the mold can be generally cylindrical of revolution around the longitudinal axis. The rotation speed of the mold around the longitudinal axis can be between 600 rpm ^-1 and 800 rpm ^-1 . Such a process makes it possible to obtain a tubular part whose mass of the non-functional part is less than or equal to 5% relative to the mass of the functional part of the tubular part.

The lateral face of the mold can be generally frustoconical of revolution around the longitudinal axis with a section which decreases in the direction of the field of gravity when the mold is positioned with the longitudinal axis aligned with the field of gravity. The rotation speed of the mold around the longitudinal axis can be between 200 rpm ^-1 and 400 rpm ^-1 , preferably between 300 rpm ^-1 and 400 rpm ^-1 . Such a process makes it possible to obtain a tubular part whose mass of the non-functional part is less than or equal to 5% relative to the mass of the functional part. In addition, such a process advantageously has a low rotation speed of the mold, which makes it possible to reduce the power necessary to drive the mold in rotation around the longitudinal axis and therefore the energy consumption of the process. Also, this makes it possible to avoid certain problems inherent to high rotation speeds such as vibrations, unbalance, or the rotation speed limit of the mold.

The side face of the mold has a frustoconical shape with a half-angle at the top defined by β=g/(ω ² (Re ₀ -e _t )) where
g is the acceleration of gravity;
ω is the rotation speed of the mold around the longitudinal axis;
Re ₀ is the external radius of a section of the tubular part which is perpendicular to the longitudinal axis and which is located at a lower end of the tubular part;
e _t is a theoretical thickness which verifies (e _t /(Re ₀ -e _t ))≤0.7.

The half-angle at the top of the side face of the mold is thus equal to the half-angle at the top of the internal face of the tubular part. The thickness of each section of the tubular part is thus identical, whatever the longitudinal position of the section on the tubular part. This makes it possible to further reduce, or even eliminate, the quantity of material forming a non-functional part of the tubular part.

The side face of the mold may include at least one relief formed annularly around the longitudinal axis. Such an annular relief makes it possible to preform parts of the turbomachine blades in the annular part.

The annular relief may be an annular groove formed in the side face of the mold. The annular relief can project radially from the side face of the mold.

The material cast in the mold may be a metal alloy, preferably a titanium aluminide (TiAl), more preferably a γ-TiAl type alloy. Titanium aluminide advantageously has good mechanical resistance at high temperatures and a low density.

The material cast in the mold may be an alloy of the γ-TiAl type and the method may further comprise heating the material to a temperature between 1550°C and 1700°C to be cast in the mold. The material poured into the mold may be molten.

The method further comprises the machining of the tubular part to produce the plurality of turbomachine blades.

Other characteristics, details and advantages will appear on reading the detailed description below, and on analyzing the attached drawings, in which:

schematically represents in perspective different stages of a known process for manufacturing a plurality of blades;

schematically represents in section a tubular part used in the process of ;

is a functional diagram of a process for manufacturing turbomachine blades according to the present description;

schematically represents in perspective a mold used in the process of according to a first embodiment;

schematically represents in section the mold of the in the section plane IV-IV;

schematically represents in section the mold of the in the section plane VV;

schematically represents in perspective a mold used in the process of according to a second embodiment;

schematically represents in section the mold of the in section plane VII-VII;

schematically represents a variant of the mold according to the first embodiment of the ;

schematically represents a variant of the mold according to the second embodiment of the .

Reference is now made to the . There is a functional diagram of a process 100 for manufacturing a plurality of turbomachine blades 10. Each blade 10 is intended to extend between a foot and a head (or heel) to have a height Ha.

The manufacturing process 100 comprises a first step 110. The first step 110 includes the supply of a mold 30. Reference is first made to Figures 4 to 6 which represent a first embodiment of the mold 30.

The mold 30 firstly comprises a tubular wall 31 extending along a longitudinal axis the longitudinal axis X. The tubular wall 31 of the mold 30 extends along the longitudinal axis X between a lower end and an upper end. The mold 30 also comprises a lower wall 33 and an upper wall 32 each extending transversely to the longitudinal axis X. The upper wall 32 and the lower wall 33 are respectively connected to the upper end and the lower end of the tubular wall 31 of the mold 30. The upper wall 32 and the lower wall 33 extend radially inwards from the tubular wall 31. In the example shown, the upper wall 32 and the lower wall 33 each extend perpendicularly to the longitudinal axis

The mold 30 also includes an internal cavity. The internal cavity is delimited by an internal side face 34 of the mold 30. The side face 34 is formed by the tubular wall 31. In other words, the side face 34 is an internal face of the tubular wall 31 of the mold 30. The side face 34 is more particularly visible in Figures 5 and 6. The internal side face 34 of the mold 30 is axisymmetric around a longitudinal axis X. The side face 34 extends along the longitudinal axis the height Ha of each blade 10. The height Hf of the side face 34 of the mold 30 is between 150 mm and 2000 mm.

The side face 34 defines a plurality of sections 34i perpendicular to the longitudinal axis shows one of the sections 34i of the side face 34. Each section 34i of the side face 34 of the mold 30 extends in a plane perpendicular to the longitudinal axis longitudinal axis X Each section 34i of the side face 34 has a radius Rf _s . The radius Rf _s of each section 34i of the side face 34 of the mold 30 is defined as being the distance separating the side face 34 from the longitudinal axis X in the plane perpendicular to the corresponding longitudinal axis X of the section 34i. The radius Rf _s of each section 34i of the side face 34 of the mold 30 is between 150 mm and 1500 mm.

Remarkably, according to the first embodiment, the side face 34 of the mold 30 is generally cylindrical of revolution around the longitudinal axis X. In other words, the radius Rf _s of each section 34i of the side face 34 is identical.

The side face 34 of the mold 30 is such that, for each section 34i, the ratio between the height Hf of the side face 34 and the radius Rf _s of the section 34i is less than or equal to 2.0. The side face 34 of the mold 30 can be such that, for each section 34i, the ratio between the height Hf of the side face 34 and the radius Rf _s of the section 34i is between 0.5 and 1.5, preferably between 0.75 and 1.25, more preferably equal to 1.0.

The internal cavity of the mold 30 is further delimited by a lower internal face 36 of the mold 30 and an upper internal face 35 of the mold 30. The lower face 36 and the upper face 35 are formed respectively by the lower wall 33 and the upper wall 32. In other words, the lower face 36 and the upper face 35 are each an internal face respectively of the lower wall 33 and the upper wall 32. The lower face 36 and the upper face 35 are respectively connected to a lower end and a upper end of the lateral face 34. In the example illustrated, the lower face 36 and the upper face 35 are preferably each perpendicular to the longitudinal axis X. Also, the lower face 36 and the upper face 35 of the mold 30 are here axisymmetric around the longitudinal axis

The manufacturing process 100 comprises a second step 120. The second step 120 includes positioning the mold 30 so that the longitudinal axis X is aligned with the gravity field g. The mold 30 is therefore positioned with the longitudinal axis X extending vertically.

The manufacturing process 100 comprises a third step 130. ^The third step 130 comprises driving the mold 30 in rotation around the longitudinal axis ^-1 .

The manufacturing method 100 comprises a fourth step 140. The fourth step 140 comprises the casting of a material in the internal cavity of the mold 30 so as to form by centrifugation a tubular part 20 extending along the longitudinal axis tubular part 20 obtained is also visible in Figures 5 and 6.

The tubular part 20 extends longitudinally between a lower end and an upper end at a height Hp which coincides with the height Hf of the lateral face 34 of the mold 30. Furthermore, the tubular part 20 has an external face 23 which coincides with the lateral face 34 of the mold 30. The external face 23 of the tubular part 20 is axisymmetric around the longitudinal axis X.

The tubular part 20 defines a plurality of sections 20i perpendicular to the longitudinal axis X. Each section 20i of the tubular part 20 extends in a plane perpendicular to the longitudinal axis to a corresponding section 34i of the side face 34 of the mold 30 which is located at the same longitudinal position. The external face 23 of the tubular part 20 therefore has, in each section 20i of the tubular part 20, a circular shape centered on the longitudinal axis X. In other words, each section 20i of the tubular part 20 has a radius external Rep _s which coincides with the radius Rf _s of the corresponding section 34i of the lateral face 34 of the mold 30. The external radius Rep _s of each section 20i of the tubular part 20 is defined as being the distance separating the external face 23 from the tubular part 20 of the longitudinal axis X in the plane perpendicular to the corresponding longitudinal axis X of the section 20i. According to the first embodiment, the external radius Rep _s of each section 20i of the tubular part 20 is identical.

In addition _, due to the rotation speed ω of the mold 30 around the longitudinal axis internal face 24 which is substantially frustoconical around the longitudinal axis 20i of the tubular part 20 has an internal radius Rip _s . The internal radius Rip _s of each section 20i of the tubular part 20 can be defined as being the distance separating the internal face 24 of the tubular part 20 from the longitudinal axis section 20i.

The internal face 24 of the tubular part 20 has a frustoconical shape including a half-angle at the top defined by γ=g/(ω ² (Re ₀ -e _t )) where
g is the acceleration of gravity;
ω is the rotation speed of the mold 30 around the longitudinal axis X;
Re ₀ is the external radius of the section 20i of the tubular part 20 located at the lower end of the tubular part 20;
e _t is a theoretical thickness which verifies (e _t /(Re ₀ - e _t ))≤0.7.

In other words, as visible at the , the profile of the internal face 24 of the tubular part 20 in a section plane comprising the longitudinal axis X is a straight line segment forming an angle equal to the half-angle γ with the longitudinal axis X.

The internal radius _{Rip s} for each _section 20i evolves linearly along the longitudinal axis
Rip _s (z) is the internal radius of a given section 20i;
Rip _s (0) is the internal radius of the section 20i of the tubular part 20 located at the lower end of the tubular part 20;
z the height of the section 20i given on the tubular part 20.

The internal radius Rip _s for each section 20i can evolve linearly along the longitudinal axis X. following the relationship Rip _s (z)=Rip _s (0)+γ*z.

A “functional” term used in reference to the parts of the tubular part 20 makes it possible to indicate whether the part thus qualified makes it possible to produce one or more blades 10. Thus, the tubular part 20 comprises a functional part 21 which contains the blades 10 with an excess thickness of material which is limited (such an excess thickness is of the order of a millimeter, preferably less than 10 mm, more preferably less than 5 mm). The functional part 21 of the tubular part 20 has a profile in a section plane comprising the longitudinal axis 20 comprises a non-functional part 22 which does not participate in the production of the blades 10. The non-functional part 22 is located radially inside the functional part 21.

Such a profile of the internal face 24 of the tubular part 20 makes it possible to reduce, or even eliminate, the quantity of material forming a non-functional part 22 of the tubular part 20. The method 100 therefore makes it possible to reduce the initial quantity of material necessary to obtain the plurality of blades 10. In other words, the method 100 improves the timing of the manufacture of the plurality of blades 10 of a turbomachine.

The fourth step 140 further comprises determining a quantity of material to be poured into the mold 30 so that each section 20i of the tubular part 20 has a thickness e _s which is greater than or equal to a theoretical thickness e _t which verifies ( e _t /(Re0-e _t ))≤0.7. This makes it possible to guarantee that the tubular part 20 has a sufficient thickness to manufacture a turbomachine blade 10 whatever the longitudinal position considered on the tubular part 20. Preferably, the thickness e _s of each section 20i of the tubular part 20 is substantially equal to the theoretical thickness. The thickness e _s of each section 20i of the tubular part 20 is considered in a radial direction relative to the longitudinal axis X. The thickness e _s of each section 20i of the tubular part 20 is defined as being the difference between the external radius Rep _s and the internal radius Rip _s of section 20i. According to the first embodiment, the thickness e _s of each section 20i of the tubular part 20 is different from the thickness e _s of each other section 20i.

In particular, the thickness e _h of the section 20i which is located at the upper end of the tubular part 20 is equal to the theoretical thickness e _t which verifies (e _t /(Re ₀ -e _t ))≤ 0.7 where Re ₀ is the external radius of the section 20i of the tubular part 20 which is located at a lower end of the tubular part 20.

Furthermore, the functional part 21 of the tubular part 20 has, for each section 20i of the tubular part 20, a thickness considered in a radial direction relative to the longitudinal axis X. The thickness of the functional part 21 is here equal to the theoretical thickness e _t for each section 20i of the tubular part 20.

Advantageously, the rotation speed of the mold 30 around the longitudinal axis X is between 600 rpm ^-1 and 800 rpm ^-1 . It is thus possible to obtain a tubular part 20 whose mass of the non-functional part 22 is less than or equal to 5% relative to the mass of the functional part 21 of the tubular part 20.

The material cast in the mold 30 is a metallic alloy of the γ-TiAl type. Such a material advantageously has good mechanical resistance at high temperatures and a low density.

The fourth step 140 also includes heating the material to a temperature between 1550°C and 1700°C to be poured into the mold 30. The material cast into the mold 30 is thus molten, which facilitates casting.

The method 100 comprises a fifth step 150. The fifth step 150 comprises the production of a plurality of turbomachine blades 10 in the tubular part 20, in particular in the functional part 21 of the tubular part 20. To do this, the part tubular 20 can be machined. The machining can first include the elimination (if necessary) of the non-functional part 22. The machining can then include the production of blades 10 in the functional part 21.

Figures 7 and 8 represent the mold 30 used in the process 100 as described above according to a second embodiment. The mold 30 according to the second embodiment differs from the mold 30 according to the first embodiment in that the lateral face 34 of the mold 30 is generally frustoconical in revolution around the longitudinal axis gravity field when the mold 30 is positioned with the longitudinal axis X aligned with the gravity field.

Thus, the radius Rf _s of each section 34i of the side face 34 is different from the radius Rf _s of each other section 34i of the side face 34. In particular, the radius Rf _s for each section 34i of the side face 34 decreases linearly along the longitudinal axis X in the direction of the gravity field.

Here too, the external face 23 of the tubular part 20 coincides with the lateral face 34 of the mold 30. The external face 23 of the tubular part is therefore generally frustoconical in revolution around the longitudinal axis direction of the gravity field when the mold 30 is positioned with the longitudinal axis X aligned with the gravity field. Therefore, the external radius Rep _s of each section 20i of the tubular part 20 is different from the external radius Rep _s of each other section 20i of the tubular part 20. In particular, the external radius Rep _s for each section 20i of the part tubular 20 decreases linearly along the longitudinal axis X in the direction of the gravity field.

Advantageously, the rotation speed of the mold 30 according to the second embodiment around the longitudinal axis X is here between 200 rpm ^-1 and 400 rpm ^-1 , preferably between 300 rpm ^-1 and 400 rpm ^-1 . Such a method 100 makes it possible to obtain a tubular part 20 whose mass of the non-functional part 22 is less than or equal to 5% relative to the mass of the functional part 21. In addition, such a method 100 advantageously presents a low rotation speed of the mold 30, which makes it possible to reduce the power necessary to drive the mold 30 in rotation around the longitudinal axis X and therefore the energy consumption of the process 100.

In addition, the side face 34 of the mold 30 has a frustoconical shape including a half-angle at the top defined by β=g/(ω ² (Re ₀ -e _t )) where
g is the acceleration of gravity;
ω is the rotation speed of the mold 30 around the longitudinal axis X;
Re ₀ is the external radius of the section 20i located at the lower end of the tubular part 20; And
e _t is a theoretical thickness which verifies (e _t /(Re ₀ -e _t ))≤0.7.

The half-angle β at the top of the lateral face 34 of the mold 30 is thus equal to the half-angle γ at the top of the internal face 24 of the tubular part 20. The thickness e _s of each section 20i of the tubular part 20 is thus identical, whatever the longitudinal position of the section on the tubular part 20. The tubular part therefore has a constant radial thickness over its entire height Hf. In the present case, this makes it possible to remove the non-functional part 22 of the tubular part 20. In other words, the use of the mold according to the second embodiment makes it possible to obtain a tubular part 20 devoid of non-functional part 22 In this case, for each section, the thickness e _s of the tubular part 20 is equal to the thickness of the functional part 21, ie in the present case to the theoretical thickness e _t .

Also remarkably, the functional part 21 of the tubular part 20 has, in the second embodiment, a profile in a section plane comprising the longitudinal axis the external face 23 of the tubular part 20.

The tubular wall 31 of the mold also has an external face 37. The external face 37 of the tubular wall 31 advantageously has a frustoconical shape. In particular, according to the example shown, the external face 37 of the tubular wall 31 here has a frustoconical shape of which a half-angle at the top is equal to the half-angle at the top β of the lateral face 34. This makes it possible to obtain constant thermal extraction over the height of the mold.

Figures 9 and 10 each represent a variant respectively of the mold 30 according to the first embodiment and of the mold 30 according to the second embodiment. In each of these variants, the lateral face 34 of the mold 30 comprises a first relief and a second relief each formed annularly around the longitudinal axis . The first annular relief 38 and the second relief are here each an annular groove formed in the side face 34 of the mold 30. The first annular relief 38 is located near the lower end of the side face 34. The second annular relief 37 is located near the upper exterior of the side face 34. The first annular relief 38 is here intended to preform the root of each blade 10 and the second annular relief 37 is intended to preform the head of each blade 10.

Claims (10)

Method (100) for manufacturing a plurality of turbomachine blades (10) of height (Ha), the method comprising:
- provide a mold (30) comprising an internal cavity, the internal cavity being delimited by an internal lateral face (34) of the mold which is axisymmetric around a longitudinal axis (X), the lateral face (34) extending along the longitudinal axis (X) according to a height (Hf) which is greater than or equal to the height (Ha) of each blade (10), the lateral face (34) defining a plurality of sections (34i) perpendicular to the axis longitudinal (X), each section (34i) of the lateral face (34) having a radius (Rf _s ), the lateral face (34) of the mold (30) being such that, for each section (34i), the ratio between the height (Hf) of the side face (34) and the radius (Rf _s ) of the section (34i) is less than or equal to 2.0;
- position the mold (30) so that the longitudinal axis (X) is aligned with the gravity field (g),
- drive the mold (30) in rotation around the longitudinal axis (X) with a rotation speed (ω) of between 200 rpm ^-1 and 800 rpm ^-1 ,
- pour a material into the internal cavity of the mold (30) so as to form by centrifugation a tubular part (20) extending along the longitudinal axis (X). Method (100) according to the preceding claim, in which the tubular part (20) obtained has a plurality of sections (20i) perpendicular to the longitudinal axis (X), the method further comprising the determination of a quantity of material to be flow into the mold (30) so that each section (20i) of the tubular part (20) has a thickness (e_s) which is greater than or equal to a theoretical thickness (e_t) who checks_t/(D₀-e_t))≤0.7 where Re₀is the external radius of the section of the tubular part (20) which is located at a lower end of the tubular part (20). Method according to any one of the preceding claims, in which the internal cavity of the mold (30) is delimited by a lower internal face (36) of the mold (30) and an upper internal face (35) of the mold, the lower face ( 36) and the upper face (35) being respectively connected to a lower end and an upper end of the lateral face (34), the lower face (36) and the upper face (35) each preferably being perpendicular to the axis longitudinal (X). Method (100) according to any one of the preceding claims, in which the lateral face (34) of the mold (30) is generally cylindrical of revolution around the longitudinal axis (X), and in which the speed of rotation (ω ) of the mold (30) around the longitudinal axis (X) is between 600 rpm ^-1 and 800 rpm ^-1 . Method (100) according to any one of claims 1 to 3, in which the lateral face (34) of the mold (30) is generally frustoconical in revolution around the longitudinal axis (X) with a section which decreases in the direction of the gravity field (g) when the mold (30) is positioned with the longitudinal axis (X) aligned with the gravity field (g), and in which the rotation speed (ω) of the mold (30) around the longitudinal axis (X) is between 200 rpm ^-1 and 400 rpm ^-1 . Method (100) according to the preceding claim, in which the lateral face (34) of the mold (30) has a frustoconical shape including a half-angle (β) at the vertex defined by β=g/(ω ² (Re ₀ -e _t )) where
g is the acceleration of gravity;
ω is the rotation speed of the mold around the longitudinal axis;
Re ₀ is the external radius of a section of the tubular part which is perpendicular to the longitudinal axis and which is located at a lower end of the tubular part;
e _t is a theoretical thickness which verifies (e _t /(Re ₀ -e _t ))≤0.7. Method (100) according to any one of the preceding claims, in which the lateral face (34) of the mold (30) comprises at least one relief (37; 38) formed annularly around the longitudinal axis (X). Method (100) according to any one of the preceding claims, in which the material cast in the mold (30) is a metal alloy, preferably a titanium aluminide (TiAl), more preferably a γ-TiAl type alloy. A method (100) according to any one of the preceding claims, wherein the material cast in the mold (30) is a γ-TiAl type alloy, the method further comprising heating the material to a temperature between 1550°C and 1700 °C to be poured into the mold (30). Method (100) according to any one of the preceding claims, the method further comprising machining the tubular part (20) to produce the plurality of turbomachine blades (10).